Common Errors in Seismic Design & How to Avoid Them. T

3 Section [12.7.2] defines the Effective Seismic Weight, W. Except for as mentioned below, live load is not included in the inertial force, however th...

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The Most Common Errors in Seismic Design …And How to Properly Avoid Them Thomas F. Heausler, P.E., S.E. Structural Engineer Kansas City, MO Abstract The paper identifies the most common errors that structural engineers make when performing seismic design and calculations. The paper demonstrates the proper application of Codes and Standards so as to avoid errors and misapplications. The paper initially focuses on low seismic risk design categories (and the surprisingly numerous seismic provisions which apply therein) and then advances to the requirements unique to high seismic risk design categories only. Introduction This paper is based upon IBC 2012, ASCE 7-10, AISC 360-10, ASIC 341-10, ACI 318-11 (including Chapter 21 and Appendix D) and other Standards. A few of the topics/common errors that are addressed include: Amplified seismic force Omega o, Cd deflection amplification, Modal analysis triggers, Rho redundancy factor, 0.7 E for Allowable Stress Design, Ev Vertical seismic effect, Vertical distribution of base shear, Orthogonal effects on corner columns, Diaphragm forces, Accidental torsion, Foundation ties, Unique calculations and detailing for Special Steel Systems, Concrete detailing and splice lengths when subject to high seismic, Wood frame hold-downs, Masonry wall anchors, and Wind governed buildings.

1. Seismic Design Category A [11.4.1] [11.7] [1.4] [1.4 General Structural Integrity] When in Seismic Design Category A, you should not use any of the provisions of Chapter 12. Instead, use the General Structural Integrity provisions of Section 1.4. Note that the General Structural Integrity provisions have some loads which may often be erroneously unaccounted for. The forces required include 1% dead load, 5% of dead plus live load for beam connections, and 20% of wall weight for wall connections. Non-Structural Components in Seismic Design Category A are exempt from Seismic Design requirements, as stated in Section 11.7.

Seismic Design and Errors

2. Importance Factor [11.5.1] [Table 1.5-2] [Table 1.5-1] [IBC Table 1604.5] The Importance factor is based upon Risk Category and the associated Life Safety, Hazard and Essential nature of the structure. Both the ASCE 7 and IBC tables should be reviewed. A typical building can sometimes evolve into an Ie equal to 1.25 or 1.5 when occupancy or use expands. Examples include relatively small churches (occupancy greater than 300), or a building where hazardous materials are stored. It should be noted that for building design Ie = 1.0, 1.25, or 1.5 but for non-structural components Ip = 1.0, or 1.5 only [13.1.3] such that Ip may not equal Ie, and in some instances Ip may be less than Ie.

This paper is written is checklist format. It is intended that an engineer could read the list so as to review and verify adequate knowledge of seismic design and common errors, as well as on a per project basis when checking a project by the engineer or by others. The basis of this paper is ASCE 7-10, and IBC 2012. Referenced sections are highlighted in brackets thus: [ASCE 7 Section Number].

3. Continuous Load Path [12.1.3] ASCE 7 has very specific provisions for many elements such collectors, connections, diaphragms, walls, etc. However, in addition to the specifics, the engineer is required by Section 12.1.3 to provide a continuous load path for all inertial forces from their origin to the foundation. Such load path shall conform to the relative stiffness and strength of the elements which exist in the structure.

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4. R Factor [Table 12.2-1 and 15.4-1, 2] The Response Modification Coefficient, R, is part of a concept where an elastic design may be performed but with due consideration of the overstrength and ductility inherent in the lateral force resisting system. In order to assure reliability in the overstrenght and ductility, many requirements are triggered with each R factor. The “R” Tables list the detailing requirements triggered. The “strings attached” to AISC R>3 structures and ACI Chapter 21 structures can be extremely significant. 5. Omega o [Table 12.2-1] When diaphragms are flexible, you are allowed to reduce the Omega zero factor by 0.5. This provision is listed in small print as footnote g, and is often overlooked by inexperienced users of ASCE 7. 6. Modal Response Spectrum Analysis Triggers [12.3] [Table 12.3-1 Horizontal Irregularities] [Table 12.3-2 Vertical Irregularities] The above tables describe various irregularities and thus trigger specific provisions. One such provision is elimination of the option of the Equivalent Lateral force Procedure [12.8] and the need to perform a Modal Dynamic Response Spectrum Analysis. The tables require close review to interpret the triggers. The ASCE Design Guide Seismic Loads: Guide to the Seismic Provisions of ASCE 7-10 by Finley Charney has a listing of the triggers in a more user friendly format. 7. Omega o Triggers [12.4] Load Combinations with Omega zero [12.2.5.2] Cantilever Columns [12.10.2.1] Collectors – Light Frame, Wood excepted [12.3.3.3] Columns, Beams Supporting Discontinuous Walls [12.13.6.5] Pile Anchorage [AISC where R>3, ACI Chapter 21, Appendix D, etc.] Omega zero is an amplification to the forces in certain elements in the seismic load path. It is required so as to prevent a weak link form occurring prior to the full energy dissipation

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and ductility potential of the primary feature of the lateral system. For example, in a steel braced frame system, in order for the diagonal brace to yield and dissipate energy in a controlled and reliable manner, all other portions of the load path (e.g. connections, bolts, welds, gusset plates, anchor bolts, columns and collectors) need to be stronger than the maximum anticipated strength, or force, in the brace. Therefore, Omega zero amplification and load combinations are specifically triggered in the sections mentioned above and in Material Standards such as AISC and ACI. 8. Redundancy - Rho Rho is a factor that penalizes structures that do not have redundancy. [12.3.4] Rho = 1.0 or 1.3. Rho = 1.0 for: SDC B, C, for Drift calculations, Fp (non-structural Components) forces, Collectors, Omega Zero Load Combinations, and Diaphragms. 9. Vertical Seismic Load Effect - Ev [12.4.2.2] requires that a vertical load effect equal to 0.2 Sds be applied to dead load. It is applied as a Dead Load Factor adjustment and may act downward or upward. It is at strength design level so it may be multiplied by 0.7 for Allowable Stress Design (ASD). No Ie, Ip, nor Rho is applied to Ev. 10. Load Combinations and Allowable Stress Design – 0.7 E For Allowable Stress Design (ASD) Load Combinations [12.4.2.3], Section [12.4.2] shall be used in lieu of [2.3.2] and [2.4.1]. Earthquake forces are at strength level so for the ASD combinations, use 0.7 E (for LRFD use 1.0 E). The 0.7 E applies to Fp non-structural component forces also. 11. Orthogonal Effects Earthquake forces shall be calculated for each of the two primary orthogonal directions. In order to consider the effects of earthquake forces at some angle other than those two directions, “orthogonal effects” must be considered. Section [12.5] requires that irregular buildings in SDC C, and corner columns in SDC D,E,F be considered with 100% of forces in one directions and 30% in other. It should be noted that IEEE 693 (Electrical Equipment) applies Orthogonal Effects to all conditions, including corner anchor bolts. 12. Effective Seismic Weight

Section [12.7.2] defines the Effective Seismic Weight, W. Except for as mentioned below, live load is not included in the inertial force, however the seismic force is later combined with dead and live loads in the load combinations. Section [12.7.2] stipulates that W shall include the following masses: 25% of Storage live load, Partitions 10 psf [4.3.2], Industrial Operating Weight – (and unbalanced conditions), 20% of snow > 30psf, and Roof Gardens. 13. Period T Section [12.8.2.1] has complex methods and limits on calculating the Period T. It should be noted that it is acceptable to use T = Ta, for simplicity. Note also, however, that the approximate formulas shall not be used for Non-building (Industrial) Structures [15.4.4]. 14. Distribute Base Shear over Height [12.8.3] Once the Base Shear, V, is calculated, it must be distributed over the height of the structure. For a one story building, all of the base shear would be applied at the roof. But for multistory structures, the base shear must be proportioned to each floor, not only in proportion to each floors mass, but also in proportion to the distance of` the floor from the base. A triangular distribution of force results for regular multi-story buildings. For distributed mass structures like stacks and CMU fences, the centroid of the load should be applied at 2/3 of the height above the base, not 1/2 height or Center of Gravity. 15. Distribute Base Shear over Height Formula [12.8.3] [Eqn 12.8-12] Fx = Cvx V Cvx = wx hxk /Sum wi hik Spreadsheets are often used to calculate the forces at each floor level. A common mistake is to have errors within the spreadsheet logic and/or calculate Cvx and then multiply it by W (total Weight) or wx weight at each floor. Cvx should be multiplied by the Base Shear V, and the sum of all the Fx should equal V. 16. Modal Response Spectrum Analysis [12.9]

The purpose of a Modal Response Spectrum Analysis is not to refine the magnitude of the Base Shear. Instead its purpose is to more accurately perform the following: 1. Distributes Base Shear over height 2. Horizontal Torsional Effects 3. Higher Mode Effects When a structural has significant vertical or horizontal irregularities, the equation 12.8-12 (triangular force distribution) becomes inaccurate. 17. Modal Analysis [12.9.4.1] Scaling of the results of Modal Response Spectrum Analysis is required and allowed. However, especially for buildings, the results of the Response Spectrum should be very similar to the Base Shear. When scaling results, one should verify that R, I, g (gravity conversion for mass) factors are included. Results must be scaled to within 85% of V as described in Section [12.9.4.1]. It is often wise to check your software results with a small regular structural model where results are predictable with hand calculations. Then confidence is gained to use the software on a large complex structural models. 18. Accidental Torsion [12.8.4.2] In addition to Inherent Torsion, Accidental torsion must be applied. This is to prevent weak torsional resisting arrangements as well as account for unexpected distribution of live load and unexpected stiffness of structural and non-structural elements. This provision applies to non-building structures as well as buildings. For torsionally irregular buildings, amplification of the accidental torsion may be required as per [12.8.4.3]. 19. Drift Check [12.12] [12.8.6 Drift Determination] [Table 12.12-1 Allowable Values] Results from the elastic analysis must be amplified by Cd to render actual expected deflections. Note that Cd is a very large value, typically a factor of about 4 or 5. The drift is then divided by Ie, because the allowable drifts are organized into a table which considers Risk Category. One should be careful when using Allowable Stress Design load combinations to not apply the 0.7E to drift calculations. 20. Diaphragm Forces

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[12.10.1.1] Forces at lower floor diaphragms may be higher than those used for the lateral force resisting system [Eqn 12.8-12] Fx=Cvx V. This is due to higher mode effects (i.e. modes higher than the first mode) where the lower floors may be accelerating higher than calculated in [Eqn 12.8-12]. The diaphragm force equation [Eqn 12.10-1] is similar to [Eqn 12.8-12], however Fpx minimums of [Eqn 12.10-2] often govern for the lower floors. 21. Fp Non-structural Components Chapter 13 [Eqn13.3.1] Non-structural components may also experience higher local accelerations due to higher mode effects as well as amplification of the force within the non-structural element itself. Industrial structures often feature very large Fp forces. It is unlikely that the Fp forces on two different floors would occur at the same point in time. Therefore one method of accounting for the Fp forces in a computer model is to run two conditions. 1. Run V load combinations with the weight of the equipment included in the seismic weight of the floor and base shear distributed over the height as per [Eqn 12.8-12]. 2. Run Fp of piece of equipment only so as to verify an adequate load path to the vertical system and/or foundation. Note also that when non-structural components get very large, i.e. 25% of total structure mass, then [15.3] Non-building Structure provisions apply. For these heavy components, a computer model capturing the stiffness and design coefficients of both the component and the primary structure must be considered together. Note that it is necessary to apply Ev to Fp combinations. And Rho (redundancy) = 1.0 and Omega zero does not apply to Fp load combinations except in ACI Appendix D calculations.

22. Wall Design

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Wall panels made of Concrete and Concrete Masonry, CMU have performed poorly in past earthquakes. The equations of ASCE 7 [12.11.1] Wall panel and [12.11.2.1] Wall Connections should be implemented as well as ACI Appendix D for anchorage. 23. Foundation Ties Foundation ties are required as per [12.13.6.2] in order to assure that the foundation system acts as an integral unit, not permitting one column or wall to move appreciably to another. This applies to pile caps in SDC C, as well as D,E,F, and Spread footings for SDC E and F. 24. Reduction of Foundation Overturning [12.13.4] allows for a reduction of the bearing pressures at the Soil-Foundation Interface. Forces may be reduced by 25% in recognition that the first mode triangular force distribution will likely not occur without higher mode effects occurring and negating the direction of the first mode, resulting reduced overall overturning moments. 25. Errata’s [ASCE 7 website] and [IBC website] have the latest errata’s. Significant entries due to typographical or unintended consequences of changes are corrected in the errata’s. 26. IBC Override’s [IBC 1613], [1613.5 Amendments to ASCE 7], [IBC Materials - Chapters 18 through 23] contain amendments to the ASCE 7 document. ASCE 7 is on a six year update cycle and IBC is on a three year. Also technical changes to IBC often have to be approved well before the issue date. Inevitably, coordination between the two and also with material standards issue (e.g. AISC, ACI etc.) must be coordinated, often through errata’s, supplements or IBC published Amendments. It is essential to periodically check for these changes. 27. ASCE 7-10 THIRD PRINTING It is recommended that the user make use of the ASCE 7 Expanded Seismic Commentary. It is 135 pages of valuable background information. It is incorporated in the Third Printing of ASCE 7 only. For those that own a First and Second Printing, you may download a .pdf file of the commentary for free from the ASCE website. This Commentary was developed by the NEHRP/BSSC Provisions Update Committee and describes the reasons for the individual provisions of the ASCE 7 Standard.

Conclusion The above listing of common errors was developed by the author during frequent review of other engineers work. This paper is based upon the author’s experience and should not be misconstrued as a consensus document of the ASCE 7 Seismic Committees. It is intended that an engineer could read the list so as to review and verify adequate knowledge of seismic design and common errors, as well as on a per project basis when checking a project designed by others. References ASCE 7-10, Minimum Design Loads for Buildings and Other Structures, Third Printing, American Society of Civil Engineers, Reston, VA IBC 2012, International Building Code 2012, International Code Council, Country Club Hills, Il ASCE Charney Ph.D., P.E., Finley A.: Seismic Loads: Guide to the Seismic Provisionsof ASCE 710, American Society of Civil Engineers, Reston, VA

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